dissipated work and fluctuation relations in driven tunneling
DESCRIPTION
Dissipated work and fluctuation relations in driven tunneling. Jukka Pekola, Low Temperature Laboratory (OVLL), Aalto University, Helsinki in collaboration with Dmitri Averin (SUNY), Olli-Pentti Saira, Youngsoo Yoon, Tuomo Tanttu, Mikko Möttönen, Aki Kutvonen, Tapio Ala-Nissila, - PowerPoint PPT PresentationTRANSCRIPT
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Dissipated work and fluctuation relations in driven tunneling
Jukka Pekola, Low Temperature Laboratory (OVLL),Aalto University, Helsinki
in collaboration withDmitri Averin (SUNY),Olli-Pentti Saira, Youngsoo Yoon,Tuomo Tanttu, Mikko Möttönen, Aki Kutvonen, Tapio Ala-Nissila, Paolo Solinas
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Contents:
1. Fluctuation relations (FRs) in classical systems, examples from experiments on molecules
2. Statistics of dissipated work in single-electron tunneling (SET), FRs in these systems
3. Experiments on Crooks and Jarzynski FRs4. Quantum FRs? Work in a two-level system
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Fluctuation relations
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FR in a ”steady-state” double-dot circuit
B. Kung et al., PRX 2, 011001 (2012).
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Crooks and Jarzynski fluctuation relations
Systems driven by control parameter(s), starting at equilibrium
FA
FB
”dissipated work”
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Jarzynski equality
Powerful expression:1. Since
The 2nd law of thermodynamics follows from JE
2. For slow drive (near-equilibrium fluctuations) one obtains the FDT by expanding JE
where
FA
FB
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Experiments on fluctuation relations: molecules
Liphardt et al., Science 292, 733 (2002)Collin et al., Nature 437, 231 (2005)Harris et al, PRL 99, 068101 (2007)
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Dissipation in driven single-electron transitions
C Cgn
Vgng
time0
1
0 tSingle-electron box
n
time
0
1
0 t
-0.5 0.0 0.5 1.0 1.5
0.0
0.2
0.4
ENER
GY
ng
n = 0 n = 1The total dissipated heat in a ramp:
D. Averin and J. P., EPL 96, 67004 (2011).
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Distribution of heat
-5 0 5 100.0
0.5
1.0
Qn = 0.1, 1, 10 (black, blue, red)
ng
time0
1
0 t
Take a normal-metal SEB
with a linear gate ramp
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Work done by the gate
In general:
For a SEB box:
for the gate sweep 0 -> 1
This is to be compared to:
J. P. and O.-P. Saira, arXiv:1204.4623
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Single-electron box with a gate ramp
For an arbitrary (isothermal) trajectory:
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Experiment on a single-electron boxO.-P. Saira et al., submitted (2012)
Detector current
Gate drive
TIME (s)
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Calibrations
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Experimental distributionsT = 214 mK
Measured distributions of Q at three different ramp frequencies
Taking the finite bandwidth of the detector into account (about 1% correction) yields
P(Q
)Q/EC
Q/EC
P(Q
)/P(-Q
)
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Measurements of the heat distributions at various frequencies and temperatures
<Q>/
E C
symbols: experiment; full lines: theory; dashed lines:
s Q /E
C
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Quantum FRs ?
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Work in a driven quantum system
Work = Internal energy + Heat
Quantum FRs have been discussed till now essentially only for closed systems(Campisi et al., RMP 2011)
P. Solinas et al., in preparation
With the help of the power operator :
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In the charge basis:
In the basis of adiabatic eigenstates:
-0.5 0.0 0.5
E g , E
e
q
EJ Ec
A basic quantum two-level system: Cooper pair box
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Quantum ”FDT”
Unitary evolution of a two-level system during the drive(Gt << 1)
in classical regime at finite T
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Relaxation after driving
Internal energy Heat
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Measurement of work distribution of a two-level system (CPB)
TIME
TR
Calorimetric measurement:
Measure temperature of the resistor after relaxation.
”Typical parameters”:
DTR ~ 10 mK over 1 ms time
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Dissipation during the gate ramp
Solid lines: solution of the full master equationDashed lines:
various e various T
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Summary
Work and heat in driven single-electron transitions analyzed
Fluctuation relations tested analytically, numerically and experimentally in a single-electron box
Work and dissipation in a quantum system: superconducting box analyzed
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Single-electron box with an overheated island
0
2
4
6
8
10
n g, n
TIME
1.0
1.2
T box/T
TIME
Linear or harmonic drive across many transitions
1
n g, nTIME
01
0G+
G-
T
T Tbox
J. P., A. Kutvonen, and T. Ala-Nissila, arXiv:1205.3951
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Back-and-forth ramp with dissipative tunneling
ng
0
1
0 t 2t
System is initially in thermal equilibrium with the bath
E
time
D0
1st
tunn
elin
g
2nd
tunn
elin
g
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Integral fluctuation relation
U. Seifert, PRL 95, 040602 (2005).G. Bochkov and Yu. Kuzovlev, Physica A 106, 443 (1981).
In single-electron transitions with overheated island:
Inserting we find that
is valid in general.
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Preliminary experiments with un-equal temperaturesP(
Q)
Q/EC
TH
T0
TN TS
Coupling to two different baths
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Maxwell’s demon
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Negative heat
-3 -2 -1 0 1 2 3 40.0
0.5
Q
Possible to extract heat from the bath
1 100.0
0.1
0.2
0.3
0.4
P(Q
<0)
n
Provides means to make Maxwell’s demon using SETs
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Maxwell’s demon in an SET trap
n
S. Toyabe et al., Nature Physics 2010
D. Averin, M. Mottonen, and J. P., PRB 84, 245448 (2011)Related work on quantum dots: G. Schaller et al., PRB 84, 085418 (2011)
”watch and move”
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Demon strategy
Energy costs for the transitions:
Rate of return (0,1)->(0,0) determined by the energy ”cost” –eV/3. If G(-eV/3) << t-1, the demon is ”successful”. Here t-1 is the bandwidth of the detector. This is easy to satisfy using NIS junctions.
Power of the ideal demon:
n
Adiabatic ”informationless” pumping: W = eV per cycleIdeal demon: W = 0